KR20060079140A - Plate type fresh water generator - Google Patents

Abstract

A plate type fresh water generator capable of generating fresh water by boiling and evaporating raw material water by a heating plate type heat exchanger (2) and condensing vapor separated in a gas-liquid separation tank (4) by a condensing plate type heat exchanger (3). To reduce the size and weight of the generator and increase a fresh-water generating capacity, the heating plate type heat exchanger (2) and the condensing plate type heat exchanger (3) are installed on one side surface (1a) of a support plate (1) so that a boiled water outlet port (6) from the heating plate type heat exchanger (2) and a vapor inlet port (9) to the condensing plate type heat exchanger (3) are opened to the other side surface (1b) of the support plate (1). The gas-liquid separation tank (4) is installed on the other side surface (1b) of the support plate (1) so that the boiled water outlet port (6) and the vapor inlet port (9) are directly opened to the inside thereof.

Description

Plate Type Water Cooling Equipment {PLATE TYPE FRESH WATER GENERATOR}

The present invention relates to a heat transfer plate for heating evaporation of the raw material water and condensation of water vapor in a fresh water device in which seawater or the like is used as raw material water, and the raw water is heated to boiling evaporation to condense the generated steam to produce fresh water. A plate type water heater using a plate type heat exchanger formed by stacking a plurality of sheets so that a fluid passage is formed therebetween.

Japanese Patent Laid-Open No. 9-299927 as a prior art discloses a plate type tide device of this kind.

That is, this plate type water heater is a heating plate type heat exchanger formed by laminating a plurality of heat exchanger plates on one side of both front and rear surfaces of a support plate so that a fluid passage is formed therebetween. A plate-type heat exchanger for condensation formed by stacking sheets to form a fluid passage therebetween is provided with a gas-liquid separation tank having a cylindrical shape on the other side thereof. Boiling evaporation is carried out by heating circulating cooling water or the like as a heat source in the engine, and the concentrated raw material water and steam evaporated by boiling are introduced into the gas-liquid separation tank, and the water vapor separated in the gas-liquid separation tank is condensed. Fresh water is introduced into a plate heat exchanger and condensed by heat exchange with cooling water. To that production.

However, the plate-type water heater in the above-described prior art is the plate-type heat exchanger for heating through the pipe pipe of a circular cross section, in which boiling water, ie, concentrated raw water and water vapor, which have been boiled and evaporated by heating in a plate-type heat exchanger for heating, is formed. The roof tile is introduced into the gas-liquid separation tank located on the opposite side with the support plate therebetween, while the vapor separated in the gas-liquid separation tank is connected to the gas-liquid separation tank and the support plate through a pipe pipe having a circular cross section. It is configured to introduce into a plate heat exchanger for condensation located on the opposite side.

For this reason, water vapor in the boiling water generated by boiling evaporation in the heating plate type heat exchanger flows into the gas-liquid separation tank through the circular pipe, and then passes through the circular pipe again in the gas-liquid separation tank to the plate heat exchanger for condensation. Since the pressure loss of the flow until it is introduced becomes large, there is a problem that the amount of evaporation of the raw material water, that is, the production amount of fresh water becomes low by the degree of this large pressure loss.

In addition, since the gas-liquid separation tank is cylindrical, it protrudes greatly from the stand supporting plate to which it is attached, so that the whole becomes very large and there is also a problem that the weight becomes large.

In addition, in the plate heat exchanger for heating of the plate type water heater of the prior art, boiling water from the plate heat exchanger for heating (concentrated raw water and steam) is seen from the stacking direction at one corner of the upper portion. The outlet of is located, while looking from the lamination direction, the supply hole of the raw material water to the heating plate type heat exchanger is located at the corner of the other end lower portion, so that between each heat exchange plate In the raw water passage in which the raw water flows into the fluid passage and is boil-evaporated, the flow becomes uneven such that congestion occurs in the flow of the raw water at the corners at the lower end and the corners at the other end. As a result, the entire surface of the heat exchanger plate cannot be effectively used for heat exchange, As well as a lower, there was a problem that can cause partial scale occurred.

It is a technical object of the present invention to provide a plate type tide device that solves these problems.

According to a first aspect of the present invention, a heating plate-type heat exchanger for boiling evaporating raw material water by heat exchange with a heating fluid, and condensation for condensing water vapor by heat exchange with a cooling fluid, on one surface side of the support plate. A plate type heat exchanger comprising a gas-liquid separation tank for separating raw material water and water vapor on the other surface side of the support plate, respectively, wherein the support plate is provided with a heating plate type heat exchanger. The boiling water outlet port communicating with the boiling water outlet passage from each raw material water passage, and the steam inlet port communicating with the steam inlet passage of each steam passage in the said plate type heat exchanger are different from the said support plate. The gas-liquid separation tank is formed so as to be open to the side of the side, and the other side of the support plate To, to characterized in that the installation can be heated above the boiling groups in plate type heat exchanger for the outlet port and the vapor inlet port of the plate type heat exchanger for the groups in the condensation so as to open directly into the gas-liquid separation tank.

With this configuration, the boiling water evaporated by boiling in the plate heat exchanger for heating, that is, water vapor and concentrated raw water, can be introduced directly into the gas-liquid separation tank without passing through the pipe piping as in the prior art. Further, since the water vapor separated in the gas-liquid separation tank can be introduced directly into the plate heat exchanger for condensation without passing through the pipe piping as in the prior art, the gas-liquid separation tank from the heating plate type heat exchanger. The pressure loss of the steam stream during the passage up to the condensing plate heat exchanger can be significantly lowered. Therefore, the amount of evaporation of the raw material water, that is, the increase in the amount of fresh water produced can be achieved as much as the pressure loss can be lowered.

Moreover, since the said gas-liquid separation tank is provided directly with respect to the support plate, without passing through a pipe piping, the whole can be made much smaller and lighter than the case of the said prior art.

The second aspect of the present invention is, in addition to the first aspect, a boiling water outlet passage in the heating plate type heat exchanger, a boiling water outlet port to which it communicates, and a steam inlet in the plate heat exchanger for condensation. The passage and the vapor inlet port to which it communicates are characterized in the form of elongated grooves which extend in parallel or approximately parallel to each other.

In this configuration, first, in the gas-liquid separation tank, the distance from the boiling water outlet port of the heating plate type heat exchanger to the steam inlet port of the condensing plate type heat exchanger is, It is much shorter than the case with the circle. Second, the flow of water vapor from the boiling water outlet port to the water vapor inlet port in the gas-liquid separation tank is smoother than in the case of the round as in the prior art, and in the heating plate type heat exchanger The fluid flow in each raw material water passage and each steam passage in the said plate heat exchanger for condensation becomes smooth. Third, a boiling water outlet passage in the heating plate type heat exchanger and a boiling water outlet port through which the heating plate type heat exchanger communicates with each other, a water vapor inlet passage in the plate type heat exchanger for condensation, and a passage in the steam inlet port communicating with the boiling water outlet port. The cross-sectional area can be made much larger than in the case of the round as in the prior art.

Therefore, since these three actions are mutually compatible, the pressure loss of the flow of water vapor can be further reduced, so that the amount of evaporation of the raw material water, that is, the increase in the production of fresh water can be further promoted.

According to a third aspect of the present invention, in addition to the first or second aspect, a boiling water outlet passage in the heating plate type heat exchanger and a boiling water outlet port to which the heating plate communicates are provided in the heating plate type heat exchanger. The heating plate is placed at a substantially center portion at the upper end as viewed from the lamination direction, and the raw water inlet passages to the respective raw water water passages in the heating plate type heat exchanger are two or more. It is located in the corner part of the left and right both sides in the lower end as seen from the lamination direction in a type heat exchanger.

When comprised in this way, when a heating plate type heat exchanger is small, raw material water will rise while boiling evaporating from the lower part toward the substantially center part in the upper side. By doing so, it is possible to avoid congestion in the flow of raw water in the lower left and right corner parts and the upper left and right corner parts, so that the entire surface of each heat exchange plate can be effectively utilized for heat exchange. It is possible to increase the efficiency by that much, and to suppress the occurrence of partial scale.

In the fourth aspect of the present invention, in addition to the first or second aspect, the boiling water outlet passage in the heating plate type heat exchanger is in the form of a horizontally long groove hole. While looking from the lamination direction in the heat exchanger, the water source inlet passages to the respective raw water water passages in the heating plate type heat exchanger are located at approximately the center of the upper end. It is located in the site | part of a lower end looking from the lamination direction in this.

In such a configuration, when the heating plate heat exchanger is small, inflow of boiling water from each raw water passage into the boiling water outlet passage is performed in each of the transverse directions. It is possible to reliably reduce the occurrence of stagnation in the flow of raw material water in the corner portions on both the left and right sides of the portion and the upper side.

In the fifth aspect of the present invention, in any of the first to fourth aspects, the heat exchange plate in the heating plate heat exchanger and the heat exchange plate in the condensation plate heat exchanger are integrated. It is characterized by consisting of a heat exchange plate.

In this configuration, the heating plate heat exchanger and the condensation plate heat exchanger have an integrated structure, so that further miniaturization and weight reduction can be achieved, and press processing of each heat exchanger plate can be simplified at once. Can be. Therefore, reduction of manufacturing cost can be achieved.

1 is a front view showing a first embodiment.

FIG. 2 is a cross-sectional view taken along the line II-II of FIG. 1.

3 is a cross-sectional view taken along line III-III of FIG. 1.

4 is a cross-sectional view taken along line IV-IV of FIG. 1.

5 is a vertical front view showing a second embodiment.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described about drawing.

1 to 4 show the first embodiment. In this figure, the code | symbol 1 shows the support plate installed by the stand type from the ground etc., and the one side side 1a in this support plate 1 has the plate heat exchanger 2 for a heating in the lower part. A condensing plate heat exchanger 3 is provided on the upper portion thereof, while a gas-liquid separation tank 4 is provided on the other side 1b of the supporting plate 1.

As shown in FIGS. 2 and 3, the heating plate type heat exchanger 2 is elongated in the horizontal direction, as is well known in the art on one side surface 1a of the support plate 1. A plurality of sheets of rectangular thin metal plate heat exchange plate 2a and a plurality of sealing bodies 2b are alternately stacked, and a face plate 2c having the laminated body disposed on one end face thereof is provided with a plurality of bolts 2d. By fastening to the said support plate 1, it is the structure which forms a plurality of raw material water passages 2e, and a plurality of heating fluid passages 2f alternately between each said heat exchange plate 2a.

Further, inside the heating plate type heat exchanger 2, two or more raw material water inlet passages 2g communicating with each of the raw material water passages 2e are viewed from the stacking direction, and the lower left and right corner portions In the portion, a boiling water outlet passage 2h communicating with the raw material water passage 2e is formed so as to extend in the lamination direction, respectively, at the substantially center portion of the upper side as viewed from the lamination direction.

In addition, inside the heating plate type heat exchanger 2, one or more heating fluid inlet passages 2i communicating with each of the heating fluid passages 2f are viewed from the lamination direction at one site. One or more heating fluid outlet passages 2j communicating with the respective heating fluid passages 2f are formed so as to extend in the lamination direction, respectively, from the lamination direction to the site on the other end side.

On the other hand, the plate-type heat exchanger 3 for condensation, as is well known in the past, on one side surface 1a of the support plate 1, as shown in Figs. A plurality of heat exchange plates 3a and a plurality of sealing bodies 3b made of thin rectangular metal plates alternately stacked, and the face plates 3c on which the laminates are arranged on one end face of the plurality of bolts 3d. By fastening to the said support plate 1 by the (), it is the structure which alternately forms several water vapor passages 3e and several cooling fluid passages 3f between each said heat exchange plate 3a.

In addition, inside the condensation plate type heat exchanger 3, one steam inlet passage 3g communicating with each of the steam passages 3e is viewed from the stacking direction, and the upper portion of the plate heat exchanger 3 is located at approximately the center of the upper side. Two or more condensed water outlet passages 3h communicating with the water vapor passages 3e are formed so as to extend in the lamination direction, respectively, at the left and right corner portions at the lower side as viewed from the lamination direction.

Further, in the condensation plate type heat exchanger 3, at least one cooling fluid inlet passage 3i communicating with each of the cooling fluid passages 3f is viewed from the lamination direction and at one end portion thereof. One or more cooling fluid outlet passages 3j communicating with each of the cooling fluid passages 3f are formed so as to extend in the lamination direction, respectively, from the lamination direction to the part on the other end side.

In addition, the support plate 1 communicates with the raw material water inlet port 5 and the boiling water outlet passage 2h which communicate with each of the raw material water inlet passages 2g in the heating plate type heat exchanger 2. Each of these ports includes a boiling water outlet port 6, a heating fluid inlet port 7 communicating with the heating fluid inlet passage 2i, and a heating fluid inlet port 8 communicating with the heating fluid outlet passage 2j. It installs so that 5-8 may open to the other side surface 1b in the support plate 1.

The support plate 1 further includes a steam inlet port 9 for communicating with a steam inlet passage 3g in the plate heat exchanger 3 for condensation, and a condensate outlet for communicating with each condensate outlet passage 3h. The port 10, the cooling fluid inlet port 11 communicating with the cooling fluid inlet passage 3i, and the cooling fluid outlet port 12 communicating with the cooling fluid outlet passage 3j, each of these ports 9-12. Is installed so as to open to the other side surface 1b of the support plate 1.

In this case, the boiling water outlet passage 2h and the boiling water outlet port 6 in the heating plate type heat exchanger 2 and the steam inlet in the plate heat exchanger 3 for condensation. The passage 3g and the steam inlet port 9 are each in the form of a groove hole that is long in the transverse direction, and the long groove hole in the boiling water outlet passage 2h and the boiling water outlet port 6; The long groove holes in the steam inlet passage 3g and the steam inlet port 9 are configured such that they are parallel or approximately parallel to each other.

And when installing the said gas-liquid separation tank 4 in the other side surface 1b in the said support plate 1, one side is opened to this gas-liquid separation tank 4, and this open side In close contact with the other side face 1b of the support plate 1, so that both the boiling water outlet port 6 and the steam inlet port 9 open directly in the gas-liquid separation tank 4, Install with a flanged joint.

The outlet 13 of the concentrated raw material water is formed in the bottom part of the gas-liquid separation tank 4. In the portion of the gas-liquid separation tank 4 between the boiling water outlet port 6 and the steam inlet port 9, a water drop remover 14 for trapping water droplets in the water vapor is provided.

In this configuration, the raw material water flows into each of the raw water passages 2e in the plate heat exchanger 2 for heating from the raw water inlet port 5 and the raw water inlet passage 2g, where It is boiled and evaporated by being heated by heat exchange with a heating fluid flowing in the heating fluid passage 2f.

The boiling water generated by the boiling evaporation, that is, steam and concentrated raw material water, is introduced into the gas-liquid separation tank 4 through the boiling water outlet passage 2h and the boiling water outlet port 6, where the steam and the concentrated raw material are The concentrated raw water separated into water and separated from the outlet 13 are discharged from the outlet 13, while the separated steam is contained in each of the steam passages 3e in the plate heat exchanger 3 for condensation. ) And the water vapor flow in through the inlet passage (3g), where it is cooled by heat exchange with the cooling fluid flowing in the neighboring cooling fluid passage (3f) to become condensed water and is taken out of the device from the condensate outlet port (10). .

In this case, the boiling water outlet port 6 in the heating plate heat exchanger 2 and the steam inlet port 9 in the plate heat exchanger 3 for condensation are a gas-liquid separation tank. By opening directly in (4), it can be from the said heat exchanger plate heat exchanger 2 to the said heat exchanger plate heat exchanger 3 via the said gas-liquid separation tank 4. The pressure loss of the steam stream is significantly lowered.

In addition, the pressure loss of the steam stream includes the boiling water outlet passage 2h and the boiling water outlet port 6 in the heating plate heat exchanger 2 and the plate heat exchanger 3 for condensation. By forming the water vapor inlet passage 3g and the water vapor inlet port 9 in the form of a long groove hole extending in parallel or substantially parallel to each other, the distance therebetween is shortened and the steam flows smoothly. As a result, the pressure loss of the steam stream can be further reduced.

In the heating plate type heat exchanger 2, the boiling water outlet passage 2h and the boiling water outlet port 6 are viewed from the lamination direction in the heating plate type heat exchanger 2. While it is located in a substantially center portion at the upper end, the two raw material water inlet passages (2 g) and the raw material water inlet port (5) in the heating plate type heat exchanger (2) provide the heating plate. By looking from the lamination direction in the type heat exchanger 2 and being located in the corner portions on both the left and right sides at the lower end, the raw material water is directed from the portions of the lower left and right corner portions to the center approximately at the upper side. Since it rises while boiling evaporating, it can avoid that stagnation arises in the flow of raw material water in the corner part of the lower left and right both sides, and the corner part of the upper left and right both sides.

In this case, three or more pieces of the raw material water inlet passage 2g and the raw material water inlet port 5 are provided, and two or more of them are located at the corner portions on the left and right sides on the lower side. You may make a structure.

In addition, when the heating plate type heat exchanger 2 is relatively small, the boiling water outlet passage 2h in the heating plate type heat exchanger 2 is in the form of a horizontally long groove hole. The raw material water passage 2e in the heating plate type heat exchanger 2 is positioned at a position approximately at the center of the upper end as viewed from the stacking direction in the heating plate type heat exchanger 2. When the raw material water inlet passage 2g to the bottom is located at the lower end portion as viewed from the stacking direction in the heating plate type heat exchanger 2, the boiling water outlet passage 2h from each raw water passage 2e. Since the inflow of boiling water into the () is performed in each part in the horizontal direction, it is possible to reliably reduce the occurrence of stagnation in the flow of raw material water in the corner portions on the lower left and right sides and the upper left and right corner portions. have.

Next, FIG. 5 shows 2nd Embodiment.

In the second embodiment, each of the heat exchange plates 2a in the heating plate heat exchanger 2 and the respective heat exchange plates 3 in the condensation plate heat exchanger 3 in the first embodiment. It is a case where it consists of one heat exchange plate by integrating the heat exchange plate 2a. The other structure is the same as that of the said 1st Embodiment.

According to this second embodiment, since the heating plate heat exchanger 2 and the condensing plate heat exchanger 3 have an integrated structure, further miniaturization and weight reduction can be achieved.

Claims (5)

On one surface side of the support plate, a heating plate type heat exchanger for boiling evaporating the raw material water by heat exchange with the heating fluid, and a plate heat exchanger for condensation for condensing water vapor by heat exchange with the cooling fluid. In the plate-type tanker which arrange | positions each gas-liquid separation tank which isolate | separates raw material water and water vapor on the other surface side in The support plate communicates with a boiling water outlet port which communicates with a boiling water outlet passage from each of the raw material water passages of the plate heat exchanger for heating, and a steam inlet passage of each of the steam passages of the plate heat exchanger for condensation. The vapor inlet port is formed so as to open to the other surface of the support plate, while the gas-liquid separation tank is formed on the other surface of the support plate, and the boiling of the boiling plate heat exchanger is performed. And a water outlet port and the steam inlet port of the plate heat exchanger for condensation so as to directly open in the gas-liquid separation tank. The boiling water outlet passage of the heating plate type heat exchanger and the boiling water outlet port to which the heating plate type heat exchanger communicates, the steam inlet passage of the plate heat exchanger for the condensation, and a steam inlet port communicating with the heating plate type heat exchanger. A plate type tide device characterized in that it is in the form of an elongated groove hole extending in parallel or approximately parallel to each other. The boiling water outlet passage in the heating plate type heat exchanger and the boiling water outlet port to which the heating plate communicates are viewed from the lamination direction in the heating plate type heat exchanger. The water source inlet passages to each of the raw material water passages of the heating plate type heat exchanger, and at least two of them, from the stacking direction of the heating plate type heat exchanger. The plate-type tide device which is located in the corner part of the right and left both sides in the lower end. The boiling water outlet passage in the heating plate type heat exchanger is in the form of a horizontally long groove hole, and is viewed from the lamination direction in the heating plate type heat exchanger. While positioned at an approximately center portion at the upper end, the raw material water inlet passages to the respective raw material water passages of the heating plate heat exchanger are viewed from the stacking direction of the heating plate type heat exchanger. Plate-type tide device, characterized in that located on the site. The heat exchange plate in the said heating plate type heat exchanger, and the heat exchange plate in the said condensation plate type heat exchanger are comprised by the integral heat exchange plate, The heat exchange plate of any one of Claims 1-4 characterized by the above-mentioned. Plate type tide device.

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